/*
 *                    BioJava development code
 *
 * This code may be freely distributed and modified under the
 * terms of the GNU Lesser General Public Licence.  This should
 * be distributed with the code.  If you do not have a copy,
 * see:
 *
 *      http://www.gnu.org/copyleft/lesser.html
 *
 * Copyright for this code is held jointly by the individual
 * authors.  These should be listed in @author doc comments.
 *
 * For more information on the BioJava project and its aims,
 * or to join the biojava-l mailing list, visit the home page
 * at:
 *
 *      http://www.biojava.org/
 *
 * Created on 08.05.2004
 *
 */


package org.jscc.app.client.biojava3.structure ;

import org.jscc.app.client.biojava3.structure.jama.Matrix;



/** utility operations on Atoms, AminoAcids, etc. 
 * <p>
 * Currently the
 * coordinates of an Atom are stored as an array of size 3
 * (double[3]). It would be more powerful to use Point3D from
 * javax.vecmath.  but unfortunately this is not a part of standard
 * java installations, since it comes with java3d . So to keep things
 * simple at the moment biojava does not depend on java3d.  
 * @author Andreas Prlic
 * @since 1.4
 * @version %I% %G%
 */

public class Calc {
    
    
    
    // 180 / pi
    static final double RADIAN = 57.29577951 ;
    
    /** Radians per degree.
     * 
     */ 
    public final static float radiansPerDegree = (float) (2 * Math.PI / 360);
    
    /** Degrees per radian.
     * 
     */
    public final static float degreesPerRadian = (float) (360 / (2 * Math.PI));
    
    
    /**
     
     *    
     */
    
    /**
     * calculate distance between two atoms.
     *
     * @param a  an Atom object
     * @param b  an Atom object
     * @return a double
     * @throws StructureException ...
     */
    public static final double getDistance(Atom a, Atom b) 
    throws StructureException
    {
        double x = a.getX() - b.getX();
        double y = a.getY() - b.getY();
        double z = a.getZ() - b.getZ();
        
        double s  = x * x  + y * y + z * z;
        
        double dist = Math.sqrt(s);
        
        return dist ;
    }
    
    
    private static final void nullCheck(Atom a) 
    throws StructureException
    {
        if  (a == null) {
            throw new StructureException("Atom is null!");
        }
    }
    
    public static final Atom invert(Atom a) throws StructureException{
    	 double[] coords = new double[]{0.0,0.0,0.0} ;
    	 Atom zero = new AtomImpl();
    	 zero.setCoords(coords);
    	 return substract(zero, a);
    }
    
    
    /** add two atoms ( a + b).
     *
     * @param a  an Atom object
     * @param b  an Atom object
     * @return an Atom object
     */
    public static final Atom add(Atom a, Atom b){
        double[] coords = new double[3] ;
        
        coords[0] = a.getX() + b.getX();
        coords[1] = a.getY() + b.getY();
        coords[2] = a.getZ() + b.getZ();
        
        Atom c = new AtomImpl();
        c.setCoords(coords);
        return c ;
    }
    
    /** substract two atoms ( a - b).
     *
     * @param a  an Atom object
     * @param b  an Atom object
     * @return an Atom object
     * @throws StructureException ...
     
     */
    public static final Atom substract(Atom a, Atom b) 
    throws StructureException
    {
        nullCheck(a) ;
        nullCheck(b) ;
        
        double[] coords = new double[3] ;
        
        coords[0] = a.getX() - b.getX();
        coords[1] = a.getY() - b.getY();
        coords[2] = a.getZ() - b.getZ();
        
        Atom c = new AtomImpl();
        c.setCoords(coords);
        return c ;
    }
    
    
    /** Vector product .
     *
     * @param a  an Atom object
     * @param b  an Atom object
     * @return an Atom object
     */
    public static final Atom vectorProduct(Atom a , Atom b){
        double[] coords = new double[3];
        
        coords[0] = a.getY() * b.getZ() - a.getZ() * b.getY();
        coords[1] = a.getZ() * b.getX() - a.getX() * b.getZ();
        coords[2] = a.getX() * b.getY() - a.getY() * b.getX();
        
        Atom c = new AtomImpl();
        c.setCoords(coords);
        return c ;
        
    }
    
    /** skalar product.
     *
     * @param a  an Atom object
     * @param b  an Atom object
     * @return a double
     */
    public static final  double skalarProduct(Atom a, Atom b){
        double skalar ;
        skalar = a.getX() * b.getX() + a.getY()* b.getY() + a.getZ() * b.getZ();
        return skalar ;
    }
    
    
    /** amount.
     *
     * @param a  an Atom object
     * @return a double
     */
    public static final double amount(Atom a){
        return Math.sqrt(skalarProduct(a,a));
    }
    
    /** angle.
     *
     * @param a  an Atom object
     * @param b  an Atom object
     * @return a double
     */
    public static final double angle(Atom a, Atom b){
        
        double skalar;
        double angle;
        
        skalar = skalarProduct(a,b);
        
        angle = skalar/( amount(a) * amount (b) );
        angle = Math.acos(angle);
        angle = angle * RADIAN ; 
        
        return angle;
    }
    
    /** return the unit vector of vector a .
     *
     * @param a  an Atom object
     * @return an Atom object
     */
    public static final Atom unitVector(Atom a) {
        double amount = amount(a) ;
        Atom U = a ;
        
        double[] coords = new double[3];
        
        coords[0] = a.getX() / amount ;
        coords[1] = a.getY() / amount ;
        coords[2] = a.getZ() / amount ;
        
        U.setCoords(coords);
        return U ;
        
    }
    
    /** torsion angle 
     * = angle between the normal vectors of the 
     * two plains a-b-c and b-c-d.
     *
     * @param a  an Atom object
     * @param b  an Atom object
     * @param c  an Atom object
     * @param d  an Atom object
     * @return a double
     * @throws StructureException ...
     */
    
    public static final double torsionAngle(Atom a, Atom b, Atom c, Atom d)
    throws StructureException
    {
        
        Atom ab = substract(a,b);
        Atom cb = substract(c,b);
        Atom bc = substract(b,c);
        Atom dc = substract(d,c);
        
        Atom abc = vectorProduct(ab,cb);	
        Atom bcd = vectorProduct(bc,dc);
        
        
        double angl = angle(abc,bcd) ;
        
        /* calc the sign: */
        Atom vecprod = vectorProduct(abc,bcd);	
        double val = skalarProduct(cb,vecprod);
        if (val<0.0) angl = -angl ;
        
        return angl;
    }
    
    /** phi angle.
     *
     * @param a  an AminoAcid object
     * @param b  an AminoAcid object
     * @return a double
     * @throws StructureException ...
     */
    public static final double getPhi(AminoAcid a, AminoAcid b)
    throws StructureException
    {
        
        if ( ! isConnected(a,b)){
            throw new StructureException("can not calc Phi - AminoAcids are not connected!") ;
        } 
        
        Atom a_C  = a.getC();
        Atom b_N  = b.getN();
        Atom b_CA = b.getCA();
        Atom b_C  = b.getC();
        
        double phi = torsionAngle(a_C,b_N,b_CA,b_C);
        return phi ;
    }
    
    /** psi angle.
     *
     * @param a  an AminoAcid object
     * @param b  an AminoAcid object
     * @return a double
     * @throws StructureException ...
     */
    public static final double getPsi(AminoAcid a, AminoAcid b)
    throws StructureException
    {
        if ( ! isConnected(a,b)) {
            throw new StructureException("can not calc Psi - AminoAcids are not connected!") ;
        }
        
        Atom a_N   = a.getN();
        Atom a_CA  = a.getCA();
        Atom a_C   = a.getC();
        Atom b_N   = b.getN();
        
        double psi = torsionAngle(a_N,a_CA,a_C,b_N);
        return psi ;
        
    }
    
    /** test if two amino acids are connected, i.e.
     * if the distance from C to N < 2,5 Angstrom.
     *
     * @param a  an AminoAcid object
     * @param b  an AminoAcid object
     * @return true if ...
     * @throws StructureException ...
     */    
    public static final boolean isConnected(AminoAcid a, AminoAcid b)
    throws StructureException
    {
        Atom C = a.getC();
        Atom N = b.getN();
        
        // one could also check if the CA atoms are < 4 A...
        double distance = getDistance(C,N);
        if ( distance < 2.5) { 
            return true ;
        } else {
            return false ;
        }
    }
    
    
    
    /** rotate a single atom aroud a rotation matrix.
     * matrix must be a 3x3 matrix.
     * @param atom atom to be rotated
     * @param m a rotation matrix represented as a double[3][3] array
     */
    public static final void rotate(Atom atom, double[][] m){

        double x = atom.getX();
        double y = atom.getY() ;
        double z = atom.getZ();
        
        double nx = m[0][0] * x + m[0][1] * y +  m[0][2] * z ;
        double ny = m[1][0] * x + m[1][1] * y +  m[1][2] * z ;
        double nz = m[2][0] * x + m[2][1] * y +  m[2][2] * z ;
        
        double[] coords = new double[3] ;
        coords[0] = nx ;
        coords[1] = ny ;
        coords[2] = nz ;
        
        atom.setCoords(coords);
    }
    
    /** Rotate a structure.
     *
     * @param structure a Structure object
     * @param rotationmatrix an array (3x3) of double representing the rotation matrix. 
     * @throws StructureException ...
     */
    public static final void rotate(Structure structure, double[][] rotationmatrix)
    throws StructureException
    {
        double[][]m = rotationmatrix;
        if ( m.length != 3 ) {
            throw new StructureException ("matrix does not have size 3x3 !");
        }
        AtomIterator iter = new AtomIterator(structure) ;
        while (iter.hasNext()) {
            Atom atom = (Atom) iter.next() ;
            Calc.rotate(atom,rotationmatrix);
        }
    }
    
    /** rotate a structure .
    *
    * @param group a group object
    * @param rotationmatrix an array (3x3) of double representing the rotation matrix. 
    * @throws StructureException ...
    */
   public static final void rotate(Group group, double[][] rotationmatrix)
   throws StructureException
   {
       double[][]m = rotationmatrix;
       if ( m.length != 3 ) {
           throw new StructureException ("matrix does not have size 3x3 !");
       }
       AtomIterator iter = new AtomIterator(group) ;
       while (iter.hasNext()) {
           Atom atom = null ;
           
           atom = (Atom) iter.next() ;
           rotate(atom,rotationmatrix);
         
       }
   }
    
   /** Rotate an atom around a Matrix object.
    * 
    * @param atom atom to be rotated
    * @param m rotation matrix to be applied to the atom
    */
   public static final void rotate(Atom atom, Matrix m){

       double x = atom.getX();
       double y = atom.getY() ;
       double z = atom.getZ();
       double[][] ad = new double[][]{{x,y,z}};
       
       Matrix am = new Matrix(ad);
       Matrix na = am.times(m);
       
       double[] coords = new double[3] ;
       coords[0] = na.get(0,0);
       coords[1] = na.get(0,1);
       coords[2] = na.get(0,2);
       atom.setCoords(coords);
   
   }
   
   /** Rotate a group object.
    * 
    * @param group  a group to be rotated
    * @param m a Matrix object representing the translation matrix
    */
   public static final void rotate(Group group, Matrix m){
       
       AtomIterator iter = new AtomIterator(group) ;
     
       while (iter.hasNext()) {
           Atom atom = (Atom) iter.next() ;
           rotate(atom,m);
           
       }
      
   }
   
    /** Rotate a structure object.
     * 
     * @param structure the structure to be rotated
     * @param m rotation matrix to be applied 
     */
    public static final void rotate(Structure structure, Matrix m){
        
        AtomIterator iter = new AtomIterator(structure) ;
      
        while (iter.hasNext()) {
            Atom atom = (Atom) iter.next() ;
            rotate(atom,m);
            
        }
       
    }
    
    /** calculate structure + Matrix coodinates ... 
     * 
     * @param s the structure to operate on
     * @param matrix a Matrix object
     */
    public static final void plus(Structure s, Matrix matrix){
        AtomIterator iter = new AtomIterator(s) ;
        Atom oldAtom = null;
        Atom rotOldAtom = null;
        while (iter.hasNext()) {
            Atom atom = null ;
            
            atom = (Atom) iter.next() ;
            try {
            if ( oldAtom != null){
                //System.out.println("before " +getDistance(oldAtom,atom));
            }
            } catch (Exception e){
                e.printStackTrace();
            }
            oldAtom = (Atom)atom.clone();
            
            double x = atom.getX();
            double y = atom.getY() ;
            double z = atom.getZ();
            double[][] ad = new double[][]{{x,y,z}};
            
            Matrix am = new Matrix(ad);
            Matrix na = am.plus(matrix);
            
            double[] coords = new double[3] ;
            coords[0] = na.get(0,0);
            coords[1] = na.get(0,1);
            coords[2] = na.get(0,2);
            atom.setCoords(coords);
            try {
                if ( rotOldAtom != null){
                    //System.out.println("after " + getDistance(rotOldAtom,atom));
                }
                } catch (Exception e){
                    e.printStackTrace();
                }
            rotOldAtom  = (Atom) atom.clone();
        }
        
    }
    
    
    
    /** shift a structure with a vector.
     *
     * @param structure  a Structure object
     * @param a          an Atom object representing a shift vector
     */
    public static final void shift(Structure structure, Atom a ){
        
        AtomIterator iter = new AtomIterator(structure) ;
        while (iter.hasNext() ) {
            Atom atom = null ;
            
            atom = (Atom) iter.next()  ;	    
           
            Atom natom = add(atom,a);	   
            double x = natom.getX();
            double y = natom.getY() ;
            double z = natom.getZ();
            atom.setX(x);
            atom.setY(y);
            atom.setZ(z);
      
        }
    }
    
    /** Shift a vector.
     * 
     * @param a vector a
     * @param b vector b
     */
    public static final void shift(Atom a, Atom b){

        Atom natom = add(a,b);      
        double x = natom.getX();
        double y = natom.getY() ;
        double z = natom.getZ();
        a.setX(x);
        a.setY(y);
        a.setZ(z);
    }
    
    /** Shift a Group with a vector.
    *
    * @param group   a group object
    * @param a          an Atom object representing a shift vector
    */
   public static final void shift(Group group , Atom a ){
       
       AtomIterator iter = new AtomIterator(group) ;
       while (iter.hasNext() ) {
           Atom atom = null ;
           
           atom = (Atom) iter.next()  ;     
          
           Atom natom = add(atom,a);       
           double x = natom.getX();
           double y = natom.getY() ;
           double z = natom.getZ();
           atom.setX(x);
           atom.setY(y);
           atom.setZ(z);
           
       }
   }
    
    
    
    /** Returns the center  of mass of the set of atoms.
     * @param atomSet a set of Atoms
     * @return an Atom representing the Centroid of the set of atoms
     */
    public static final Atom getCentroid(Atom[] atomSet){
        
        double[] coords = new double[3];
        
        coords[0] = 0;
        coords[1] = 0;
        coords[2] = 0 ;
        
        for (int i =0 ; i < atomSet.length; i++){
            Atom a = atomSet[i];
            coords[0] += a.getX();
            coords[1] += a.getY();
            coords[2] += a.getZ();
        }
        
        int n = atomSet.length;
        coords[0] = coords[0] / n;
        coords[1] = coords[1] / n;
        coords[2] = coords[2] / n;
        
        Atom vec = new AtomImpl();
        vec.setCoords(coords);
        return vec;
        
    }
    
    /** Returns the Vector that needs to be applied to shift a set of atoms
     * to the Centroid.
     * @param atomSet array of Atoms  
     * @return the vector needed to shift the set of atoms to its geometric center
     */
    public static final Atom getCenterVector(Atom[] atomSet){
        Atom centroid = getCentroid(atomSet);
        
       return getCenterVector(atomSet,centroid);
        
    }
    
    /** Returns the Vector that needs to be applied to shift a set of atoms
     * to the Centroid, if the centroid is already known
     * @param atomSet array of Atoms  
     * @return the vector needed to shift the set of atoms to its geometric center
     */
    public static final Atom getCenterVector(Atom[] atomSet, Atom centroid){
        
        
        double[] coords = new double[3];
        coords[0] = 0 - centroid.getX();
        coords[1] = 0 - centroid.getY();
        coords[2] = 0 - centroid.getZ();
        
        Atom shiftVec = new AtomImpl();
        shiftVec.setCoords(coords);
        return shiftVec;
        
    }
    
   
    /** Center the atoms at the Centroid. 
     * @param atomSet a set of Atoms
     * @return an Atom representing the Centroid of the set of atoms
     * @throws StructureException 
     * */
    public static final Atom[] centerAtoms(Atom[] atomSet) throws StructureException {
       
    	Atom centroid = getCentroid(atomSet);
    	return centerAtoms(atomSet, centroid);
    }
    
    /** Center the atoms at the Centroid, if the centroid is already know.
     * @param atomSet a set of Atoms
     * @return an Atom representing the Centroid of the set of atoms
     * @throws StructureException 
     * */
    public static final Atom[] centerAtoms(Atom[] atomSet, Atom centroid) throws StructureException {
       
        Atom shiftVector = getCenterVector(atomSet, centroid);
        
        Atom[] newAtoms = new AtomImpl[atomSet.length];
        
        for (int i =0 ; i < atomSet.length; i++){
            Atom a = atomSet[i];
            Atom n = add(a,shiftVector);
            newAtoms[i] = n ;
        }
        return newAtoms;
    }
    
    
   
    
    /** creates a virtual C-beta atom. this might be needed when working with GLY
     * 
     * thanks to Peter Lackner for a python template of this method.
     * @param amino the amino acid for which a "virtual" CB atom should be calculated 
     * @return a "virtual" CB atom
     * @throws StructureException
     */
    public static final Atom createVirtualCBAtom(AminoAcid amino) 
    throws StructureException{
        
        AminoAcid  ala = StandardAminoAcid.getAminoAcid("ALA");
        Atom aN  = ala.getN();
        Atom aCA = ala.getCA();
        Atom aC  = ala.getC();
        Atom aCB = ala.getCB();
        
        
        Atom[] arr1 = new Atom[3];
        arr1[0] = aN;
        arr1[1] = aCA;
        arr1[2] = aC;
        
        Atom[] arr2 = new Atom[3];
        arr2[0] = amino.getN();
        arr2[1] = amino.getCA();
        arr2[2] = amino.getC();
        
        // ok now we got the two arrays, do a SVD:
        
        SVDSuperimposer svd = new SVDSuperimposer(arr2,arr1);
        
        Matrix rotMatrix = svd.getRotation();
        Atom tranMatrix = svd.getTranslation();
                    
        Calc.rotate(aCB,rotMatrix);

        Atom virtualCB = Calc.add(aCB,tranMatrix);
        virtualCB.setName("CB");
        virtualCB.setFullName(" CB ");
        
        return virtualCB;
    }    
    
    
    /**Gget euler angles for a matrix given in ZYZ convention.
     * (as e.g. used by Jmol)
     * 
     * @param m the rotation matrix
     * @return the euler values for a rotation around Z, Y, Z in degrees...
     */
    public static final double[] getZYZEuler(Matrix m) {
        double m22 = m.get(2,2);
        double rY = (float) Math.acos(m22) * degreesPerRadian;
        double rZ1, rZ2;
        if (m22 > .999d || m22 < -.999d) {
          rZ1 = (double) Math.atan2(m.get(1,0),  m.get(1,1)) * degreesPerRadian;
          rZ2 = 0;
        } else {
          rZ1 = (double) Math.atan2(m.get(2,1), -m.get(2,0)) * degreesPerRadian;
          rZ2 = (double) Math.atan2(m.get(1,2),  m.get(0,2)) * degreesPerRadian;
        }
        return new double[] {rZ1,rY,rZ2};
    }
    
    
    /** Convert a rotation Matrix to Euler angles.
     *   This conversion uses conventions as described on page:
     *   http://www.euclideanspace.com/maths/geometry/rotations/euler/index.htm
     *   Coordinate System: right hand
     *   Positive angle: right hand
     *   Order of euler angles: heading first, then attitude, then bank
     *   
     * @param m the rotation matrix
     * @return a array of three doubles containing the three euler angles in radians
     */   
    public static final double[] getXYZEuler(Matrix m){
        double heading, attitude, bank;
        
        // Assuming the angles are in radians.
        if (m.get(1,0) > 0.998) { // singularity at north pole
            heading = Math.atan2(m.get(0,2),m.get(2,2));
            attitude = Math.PI/2;
            bank = 0;
            
        } else if  (m.get(1,0) < -0.998) { // singularity at south pole
            heading = Math.atan2(m.get(0,2),m.get(2,2));
            attitude = -Math.PI/2;
            bank = 0;
            
        } else {
            heading = Math.atan2(-m.get(2,0),m.get(0,0));
            bank = Math.atan2(-m.get(1,2),m.get(1,1));
            attitude = Math.asin(m.get(1,0));
        }
        return new double[] { heading, attitude, bank };
    }
    
    
    
    /** This conversion uses NASA standard aeroplane conventions as described on page:
    *   http://www.euclideanspace.com/maths/geometry/rotations/euler/index.htm
    *   Coordinate System: right hand
    *   Positive angle: right hand
    *   Order of euler angles: heading first, then attitude, then bank.
    *   matrix row column ordering:
    *   [m00 m01 m02]
    *   [m10 m11 m12]
    *   [m20 m21 m22]
     * @param heading in radians
     * @param attitude  in radians
     * @param bank  in radians
     * @return the rotation matrix */
    public static final  Matrix matrixFromEuler(double heading, double attitude, double bank) {
        // Assuming the angles are in radians.
        double ch = Math.cos(heading);
        double sh = Math.sin(heading);
        double ca = Math.cos(attitude);
        double sa = Math.sin(attitude);
        double cb = Math.cos(bank);
        double sb = Math.sin(bank);

        Matrix m = new Matrix(3,3);
        m.set(0,0, ch * ca);
        m.set(0,1, sh*sb - ch*sa*cb);
        m.set(0,2, ch*sa*sb + sh*cb);
        m.set(1,0, sa);
        m.set(1,1, ca*cb);
        m.set(1,2, -ca*sb);
        m.set(2,0, -sh*ca);
        m.set(2,1, sh*sa*cb + ch*sb);
        m.set(2,2, -sh*sa*sb + ch*cb);
        
        return m;
    }
    

}


